The Last RNA-Binding Repeat of the
            <i>Escherichia coli</i>
            Ribosomal Protein S1 Is Specifically Involved in Autogenous Control

et al. 2015

Langmuir

Desalination of high-salinity solutions has been studied using a novel experimental technique and a theoretical model. Neutron imaging has been employed to visualize lithium ions in mesoporous carbon materials, which are used as electrodes in capacitive deionization (CDI) for water desalination. Experiments were conducted with a flow-through CDI cell designed for neutron imaging and with lithium-6 chloride ((6)LiCl) as the electrolyte. Sequences of neutron images have been obtained at a relatively high concentration of (6)LiCl solution to provide information on the transport of ions within the electrodes. A new model that computes the individual ionic concentration profiles inside mesoporous carbon electrodes has been used to simulate the CDI process. Modifications have also been introduced into the simulation model to calculate results at high electrolyte concentrations. Experimental data and simulation results provide insight into why CDI is not effective for desalination of high ionic-strength solutions. The combination of experimental information, obtained through neutron imaging, with the theoretical model will help in the design of CDI devices, which can improve the process for high ionic-strength solutions.

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Drag coefficient and settling velocity for particles of cylindrical shape

2008

Powder Technology

Chemical Engineering Journal

Seawater desalination by over-potential membrane capacitive deionization: Opportunities and hurdles

Tang

Kim

Chang

et al. 2019

Volume Averaging Study of the Capacitive Deionization Process in Homogeneous Porous Media

2015

Transp Porous Med

Carbon dioxide capture with aqueous amino acids: Mechanistic study of amino acid regeneration by guanidine crystallization and process intensification

Kasturi

Separation and Purification Technology

et al. 2021

Modeling Sulfur Poisoning of Palladium Membranes Used for Hydrogen Separation

International Journal of Chemical Engineering

2019

Hydrocarbons are the most important source for hydrogen production. A combined reaction-separation process using inorganic membranes can significantly increase the reaction conversion by shifting the equilibrium toward product formation. Sulfur poisoning is a significant problem as it deactivates the most commonly used metallic membranes. The relationship of the membrane activity and surface coverage with the surface structure has been recognized in the literature. A theoretical model to simulate hydrogen transport in the presence of sulfur compounds is presented. This model accounts for active site deactivation and permanent structural damage to the membrane. Transport and reaction rate parameters used in the model have been estimated from experimental data. Qualitatively, the model represents well the behavior of inorganic membranes, including partial membrane activity regeneration after the sulfur source is removed.

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Ocean Disposal of CO₂: Conditions for Producing Sinking CO₂Hydrate

Journal of Dispersion Science and Technology

Riestenberg

Lee

et al. 2005